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Literature DB >> 17541594

Graph-theoretic methods for the analysis of chemical and biochemical networks. I. Multistability and oscillations in ordinary differential equation models.

Abstract

A chemical mechanism is a model of a chemical reaction network consisting of a set of elementary reactions that express how molecules react with each other. In classical mass-action kinetics, a mechanism implies a set of ordinary differential equations (ODEs) which govern the time evolution of the concentrations. In this article, ODE models of chemical kinetics that have the potential for multiple positive equilibria or oscillations are studied. We begin by considering some methods of stability analysis based on the digraph of the Jacobian matrix. We then prove two theorems originally given by A. N. Ivanova which correlate the bifurcation structure of a mass-action model to the properties of a bipartite graph with nodes representing chemical species and reactions. We provide several examples of the application of these theorems.

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Year: 2007 PMID： 17541594 DOI： 10.1007/s00285-007-0099-1

Source DB: PubMed Journal: J Math Biol ISSN： 0303-6812 Impact factor: 2.259

27 in total

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Review 3. Roles of positive and negative feedback in biological systems.

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5. A theoretical graph method for search and analysis of critical phenomena in biochemical systems. II. Kinetic models of biochemical oscillators including two and three substances.

Authors: G L Ermakov
Journal: Biochemistry (Mosc) Date: 2003-10 Impact factor: 2.487

6. Switching mechanism for branched biochemical fluxes: graph-theoretical analysis.

Authors: Boris Goldstein
Journal: Biophys Chem Date: 2006-10-02 Impact factor: 2.352

7. Concerning oscillations.

Authors: D A Walker
Journal: Photosynth Res Date: 1992-12 Impact factor: 3.573

Review 8. A model for circadian oscillations in the Drosophila period protein (PER).

Authors: A Goldbeter
Journal: Proc Biol Sci Date: 1995-09-22 Impact factor: 5.349

9. Simplifying principles for chemical and enzyme reaction kinetics.

Authors: W Klonowski
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10. Signaling switches and bistability arising from multisite phosphorylation in protein kinase cascades.

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14 in total

1. Graph-theoretic methods for the analysis of chemical and biochemical networks. II. Oscillations in networks with delays.

Authors: Maya Mincheva; Marc R Roussel
Journal: J Math Biol Date: 2007-05-31 Impact factor: 2.259

Graph-theoretic methods for the analysis of chemical and biochemical networks. I. Multistability and oscillations in ordinary differential equation models.

Review 1. Metabolic pathway analysis: basic concepts and scientific applications in the post-genomic era.

2. Multistationarity, the basis of cell differentiation and memory. I. Structural conditions of multistationarity and other nontrivial behavior.

Review 3. Roles of positive and negative feedback in biological systems.

4. What makes biochemical networks tick?

5. A theoretical graph method for search and analysis of critical phenomena in biochemical systems. II. Kinetic models of biochemical oscillators including two and three substances.

6. Switching mechanism for branched biochemical fluxes: graph-theoretical analysis.

7. Concerning oscillations.

Review 8. A model for circadian oscillations in the Drosophila period protein (PER).

9. Simplifying principles for chemical and enzyme reaction kinetics.

10. Signaling switches and bistability arising from multisite phosphorylation in protein kinase cascades.

1. Graph-theoretic methods for the analysis of chemical and biochemical networks. II. Oscillations in networks with delays.

2. Bistability and oscillations in chemical reaction networks.

3. Some possible dynamical constraints for life's origin.

4. The interaction graph structure of mass-action reaction networks.

5. Multistationarity in mass action networks with applications to ERK activation.

Review 6. Network representations and methods for the analysis of chemical and biochemical pathways.

7. Laplacian Dynamics with Synthesis and Degradation.

8. Morphisms of reaction networks that couple structure to function.

9. GraTeLPy: graph-theoretic linear stability analysis.

10. Structural identifiability of cyclic graphical models of biological networks with latent variables.